KR20170114616A - Vacuum interubter for a circuit breaker - Google Patents

Abstract

According to the present invention, the center shield is positioned between the upper insulating vessel and the lower insulating vessel so that the center shield is not provided inside the insulating vessel, thereby reducing the outer diameter of the insulating vessel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vacuum interrupter for a vacuum interrupter,

The present invention relates to a vacuum interrupter for a vacuum interrupter, and more particularly, to a vacuum interrupter for a vacuum interrupter, in which a center shield provided in a vacuum interrupter is positioned in the same line as an insulating container, thereby reducing the overall size of the insulating container, To a vacuum interrupter.

Generally, circuit breaker and switchgear are devices that directly control the power supply to the load by opening and closing the electric circuit in the power system. From breakers with the ability to shut off the fault current to the fault current, and switchgears opening and closing the load current Widely used.

These breakers are classified into hydraulic breakers, air breakers, gas breakers and vacuum breakers depending on the insulation medium of the core part.

Among them, the vacuum circuit breaker is small, has high reliability, has excellent opening and closing characteristics, and is easily used for maintenance, which is widely used from small voltage to high voltage and large capacity.

On the other hand, the vacuum interrupter is used as a shutoff part of a vacuum circuit breaker. In order to change the open / close state of the high voltage circuit by detecting a current or voltage generated in the high voltage line of the high voltage circuit in the housing assembly, When the actuator is linearly reciprocated, the movable electrode portion of the vacuum interrupter installed on one side of the actuator contacts and separates from the fixed electrode portion to supply and cut off electric power.

1 is a cross-sectional view of a vacuum interrupter 10 provided in a conventional vacuum circuit breaker.

1, in the conventional vacuum interrupter 10, an insulating container 13 made of four ceramics is sealed by a fixing flange 11 and a movable flange 12, A fixed electrode portion 14 having a fixed electrode 14a at one end and a movable electrode portion 15 having a movable electrode 15a contacting or separating from the fixed electrode portion 14 are disposed to face each other And a center shield 16 and an auxiliary shield 17 are provided.

At this time, the center shield 16 is disposed at the center between the movable electrode 15a and the fixed electrode 14a on the inner side of the insulating container 13, and the auxiliary shield 17 is disposed in the insulating container 13, On the upper side and the lower side of the center shield 16, respectively.

However, in the vacuum interrupter 10 of the conventional vacuum circuit breaker constructed as described above, since the center shield 16 and the auxiliary shield 17 are located inside the insulating container 13, the outer diameter of each shield 16, The inner diameter of the insulating container 13 must be large and the size of the insulating container 13 in which the respective shields 16 and 17 are accommodated must be made large.

In addition, since the size of the vacuum interrupter 10 is increased, the amount of the ceramic constituting the vacuum interrupter 10 is increased, and the manufacturing cost is greatly increased.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a vacuum interrupter which can reduce the size of an insulating container and reduce manufacturing cost by arranging a center shield, And a vacuum interrupter.

The above-described object of the present invention is achieved by an upper insulating container, A lower insulating container located below the upper insulating container; A fixed electrode unit fixedly installed inside the upper insulating vessel; A movable electrode part installed inside the lower insulating container so as to face the fixed electrode part and contacting or separating to the fixed electrode part; And a center shield disposed between the upper insulating vessel and the lower insulating vessel to receive the fixed electrode unit and the movable electrode unit.

And a first auxiliary shield provided inside the upper insulating vessel and the lower insulating vessel.

Further, the outer diameter of the center shield is equal to or larger than the inner diameter of the upper insulating container and the lower insulating container.

The fixed electrode may be formed with a fixed electrode at one end thereof, and a movable electrode may be formed at one end of the movable electrode to contact or separate the fixed electrode. The inner diameter of the fixed electrode or the movable electrode, And the distance between the electrodes is equal to or greater than the sum of the distances between the electrodes.

The upper insulating container includes a first upper container and a second upper container which is located below the first upper container and which is adapted to sandwich the fixing portion between the first upper container and the first upper container. Wherein the lower insulating container comprises a first lower container and a second lower container positioned below the first lower container and interposed between the first lower container and the second lower container .

The first upper container, the second lower container, the second upper container, and the first lower container have the same upper and lower lengths.

And a second auxiliary shield is formed between the upper insulating container and the center shield and between the lower insulating container and the center shield.

Further, the second auxiliary shield is formed with protrusions so as to protrude outward.

The protrusion may be integrally formed with the second auxiliary shield or may be interconnected through welding.

Further, the projecting portion is characterized in that one end is curved inward to have a circular or curved shape.

And the upper end of the upper insulating vessel and the lower end of the lower insulating vessel are provided with flanges to seal the inside thereof.

As described above, the vacuum interrupter of the vacuum interrupter of the present invention has an effect that the center shield is positioned between the upper insulating container and the lower insulating container, thereby reducing the vertical length of the insulating container.

Further, since the center shield is positioned between the upper insulating vessel and the lower insulating vessel, the center shield is not provided inside the insulating vessel, thereby reducing the outer diameter of the insulating vessel.

In addition, the upper and lower lengths and the outer diameters of the insulating container are reduced so that the total size of the insulating container is reduced, thereby reducing the amount of ceramic used for manufacturing the insulating container.

Also, the protrusion is formed on the second sub-shield, and one end of the protrusion is formed to be rounded or bent so as to prevent the concentration of the electric field on the contact area between the center shield and the upper insulating vessel and the lower insulating vessel, that is, Thereby preventing occurrence of partial discharge or dielectric breakdown.

1 is a sectional view of a vacuum interrupter provided in a conventional vacuum circuit breaker;
2 is a sectional view showing a vacuum interrupter provided in a vacuum interrupter according to the present invention;
3 is a sectional view showing a vacuum interrupter provided in a vacuum interrupter according to the present invention.
4 is a partially enlarged view showing a second auxiliary shield of a vacuum interrupter provided in a vacuum interrupter according to the present invention;

Hereinafter, a vacuum interrupter of a vacuum interrupter according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view of a vacuum interrupter provided in a vacuum interrupter according to the present invention, FIG. 3 is a sectional view showing a vacuum interrupter provided in a vacuum interrupter according to the present invention, Fig. 6 is a partially enlarged view showing a second auxiliary shield of a vacuum interrupter; Fig.

2 and 3, the vacuum interrupter 100 of the vacuum interrupter according to the present invention includes an upper insulating container 111, a lower insulating container 113, a fixed electrode part 115, a movable electrode part 117 A center shield 119, and a first sub-shield 121. The sub-

The upper insulating container 111 is made of ceramic or tempered glass and forms an upper side enclosure such that the fixed electrode part 115 is located inside.

The lower insulating vessel 113 Ceramic or tempered glass, and forms a lower side enclosure such that the movable electrode part 117 is located inside.

The fixed electrode part 115 is provided inside the upper insulating container 111 and a fixed electrode 115a is provided at one end so that the movable electrode part 117 contacts with the movable electrode part 117 as the movable electrode part 117 moves. Or separated.

The movable electrode part 117 is disposed inside the lower insulating container 113 so as to face the fixed electrode part 115 and has movable electrodes 117a at one end thereof to move up and down the fixed electrode part 115, / RTI >

The center shield 119 is used to prevent metal vapor generated at the time of interruption of current from being deposited on the inner wall surface of each of the insulating containers 111 and 113. The center shield 119 is made of stainless steel or copper, And the lower insulating container 113. The lower insulating container 113 is formed of an insulating material.

And is connected to one end and the other ends of the upper insulating vessel 111 and the lower insulating vessel 113 through welding such as blazing to allow the fixed electrode part 115 and the movable electrode part 117 to be accommodated It forms a central enclosure.

At this time, the center shield 119 is not provided inside each of the insulating containers 111 and 113 but is positioned between the upper insulating container 111 and the lower insulating container 113, 113 is made smaller.

The outer diameter D1 of the center shield 119 is formed to be equal to or greater than the inner diameters D2 and D3 of the upper insulating container 111 and the lower insulating container 113. [

Since the thickness of the center shield 119 is thinner than the thickness of the upper insulating container 111 and the lower insulating container 113, the outer diameter D1 of the center shield 119 is smaller than the outer diameter of the upper insulating container 111 The outer diameter D1 of the center shield 119 is smaller than the outer diameter of the lower insulating vessel 113 and the outer diameter D1 of the center insulating shield 113 is smaller than the outer diameter of the lower insulating vessel 113. [ May be formed larger than the outer diameter.

The inner diameter of the center shield 119 is formed to be equal to or greater than the sum of the outer diameter D4 of the fixed electrode 115a or the movable electrode 117a and the interelectrode distance D5, The current is prevented from flowing from the fixed electrode 115a to the movable electrode 117a by riding the center shield 119 so that the vacuum interrupter 100 (100a, 100b) To prevent the occurrence of dielectric breakdown.

The first auxiliary shield 121 is provided inside the upper insulating vessel 111 and the lower insulating vessel 113, respectively.

The first sub-shield 121 is provided with a first sub-shield 111a and a second sub-container 113b to be sandwiched between a first upper container 111a and a second upper container 111b or between a first lower container 113a and a second lower container 113b A portion 121a is formed.

The upper insulating container 111 includes a first upper container 111a and a second upper container 111b positioned below the first upper container 111a. The first auxiliary shield 121 is closely attached to the upper insulating container 111 by fitting the fixing portion 121a between the second upper container 111b and the second upper container 111b.

The lower insulating container 113 is composed of a first lower container 113a and a second lower container 113b positioned below the first lower container 113a, The first auxiliary shield 121 is positioned inside the lower insulating container 113 by being sandwiched between the first lower container 113a and the second lower container 113b.

At this time, the first upper container 111a and the second lower container 113b are formed so that the upper and lower lengths L1 and L4 are the same, and the second upper container 111b and the first lower container 113a The upper and lower lengths L2 and L3 are also formed to be the same.

Accordingly, the symmetry of each container constituting the enclosure of the vacuum interrupter 100 is improved, so that the insulation performance of the vacuum interrupter 100 is maintained.

That is, a voltage for energizing the current is applied to the upper side where the first upper container 111a and the second upper container 111b are located, or the voltage for passing the current between the first lower container 113a and the second lower container 113b Since the upper and lower containers 111a and 111b and the corresponding lower containers 113a and 113b have the same size with respect to the voltage to be applied, So that the insulation performance remains constant irrespective of whether the voltage is applied to the upper side or the lower side.

A second auxiliary shield 123 is formed between the upper insulating container 111 and the center shield 119 and between the lower insulating container 113 and the center shield 119.

As shown in FIG. 4, the second sub-shield 123 is formed with a protrusion 123a so as to protrude outward. The protrusion 123a is formed such that one end thereof is curved inward and is circular or curved.

At this time, the protrusion 123a may be integrally formed with the second auxiliary shield 123 or may be separately manufactured and interconnected through welding.

Therefore, since the one end of the protrusion 123a is formed in a curved shape or a curved shape, the joint between the center shield 119 and the upper insulating vessel 111 and the lower insulating vessel 113, Thereby preventing partial electric discharge or breakdown of the insulation from occurring on the junction.

A flange 130 is provided at the upper end of the upper insulating vessel 111 and the lower end of the lower insulating vessel 113 to connect the upper end of the upper insulating vessel 111 and the lower insulating vessel 111 113) to seal the inside thereof.

The vacuum interrupter 100 of the vacuum breaker of the present invention operated as described above is constructed such that the center shield 119 is positioned between the upper insulating container 111 and the lower insulating container 113, To be reduced.

The center shield 119 is positioned between the upper insulating container 111 and the lower insulating container 113 so that the center shield 119 is not provided inside the insulating containers 111 and 113, And 113 are reduced.

The total length of the insulating containers 111 and 113 is reduced so that the lengths and lengths of the insulating containers 111 and 113 are reduced so that the amount of ceramic used for manufacturing the insulating containers 111 and 113 is reduced Thereby significantly reducing costs.

The protrusion 123a is formed in the second auxiliary shield 123 and the center shield 119 and the upper insulating vessel 111 and the lower insulating vessel 113 are formed so that one end of the protrusion 123a is curved or bent. ), That is, the concentration of the electric field generated on the joint portion through brazing welding is prevented, thereby preventing the occurrence of partial discharge or dielectric breakdown on the joint portion.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the above description does not limit the scope of the present invention defined by the limitations of the following claims.

10, 100: vacuum interrupter 11: fixed flange
12: movable flange 13: insulating container
14: fixed electrode part 14a: fixed electrode
15: movable electrode part 15a: movable electrode
16: center shield 17: auxiliary shield
111: upper insulating container 111a: first upper container
111b: second upper container 113: lower insulating container
113a: first lower vessel 115: fixed electrode part
115a: fixed electrode 117: movable electrode part
117a: movable electrode 119: center shield
121: first auxiliary shield 121a:
123: second auxiliary shield 123a:
130: Flange

Claims (11)

An upper insulating container;
A lower insulating container located below the upper insulating container;
A fixed electrode unit fixedly installed inside the upper insulating vessel;
A movable electrode part installed inside the lower insulating container so as to face the fixed electrode part and contacting or separating to the fixed electrode part; And
A center shield disposed between the upper insulating vessel and the lower insulating vessel to receive the fixed electrode unit and the movable electrode unit;
And the vacuum interrupter. The method according to claim 1,
Further comprising a first auxiliary shield provided in the upper insulating vessel and the lower insulating vessel. The method according to claim 1,
Wherein an outer diameter of the center shield is equal to or larger than an inner diameter of the upper insulating container and the lower insulating container. The method according to claim 1,
A fixed electrode is formed at one end of the fixed electrode unit,
A movable electrode which is in contact with or separated from the fixed electrode is formed at one end of the movable electrode,
Wherein an inner diameter of the center shield is equal to or greater than a sum of an outer diameter of the fixed electrode or the movable electrode and a distance between the electrodes. 3. The method of claim 2,
The first auxiliary shield is provided with a fixing portion,
Wherein the upper insulating container comprises a first upper container and a second upper container positioned below the first upper container to sandwich the fixing portion between the first upper container and the first upper container,
Wherein the lower insulating container comprises a first lower container and a second lower container positioned below the first lower container and adapted to fit the fixing portion between the first lower container and the first lower container. Vacuum interrupter. 6. The method of claim 5,
And the upper and lower lengths of the first upper container, the second lower container, the second upper container, and the first lower container are the same. 3. The method of claim 2,
And a second auxiliary shield is formed between the upper insulating container and the center shield and between the lower insulating container and the center shield. 8. The method of claim 7,
And the second auxiliary shield is formed with a protrusion so as to protrude outward. 9. The method of claim 8,
Wherein the protrusion is formed integrally with the second sub-shield or interconnected through welding. ≪ RTI ID = 0.0 > 8. < / RTI > 9. The method of claim 8,
Wherein the protruding portion has a circular or curved shape with one end curved inward. The method according to claim 1,
Wherein a flange is provided at an upper end of the upper insulating container and a lower end of the lower insulating container to seal the inside of the lower insulating container.

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